Hydro-Mechanical Properties of an Unsaturated Frictional Material

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260 BIBLIOGRAPHY Phene, C. J., Hoffman, G. J. & Rawlins, S. L. (1971), ‘Measuring soil matric potential in situ by sensing heat dissipation with a porous body: Theory and sensor contruction’, Soil Science Society of America Journal 35, 27–32. Philip, J. R. (1964), ‘Similarity hypothesis for capillary hysteresis in porous materials’, Journal of Geophysical Research 69, 1553–1562. Plagge, R., Häupl, P. & Renger, M. (1997), Transient effects on the hydraulic properties of porous media, in F. J. L. M. Th. Van Genuchten & L. Wu, eds, ‘Proc. of the Int. Workshop on Characterization and Measurement of the Hydraulic Properties of Unsaturated Porous Media’, University of California, Riverside, CA., pp. 905–912. Poulovassilis, A. (1962), ‘Hysteresis of pore water - An application of the concept of indepen- dent domains’, Soil Science 92, 405–412. Poulovassilis, A. (1969), ‘The effect of hysteresis of pore water on the hydraulic conductivity’, Journal of Soil Science 20(1), 52–56. Poulovassilis, A. (1970), ‘Hysteresis of pore water in granular porous bodies’, Soil Science 109(1), 5–12. Poulovassilis, A. & El-Gharmy, W. M. (1978), ‘The dependent domain theory applied to scanning curves of any order in hysteretic soil water relationship’, Journal of Soil Science 126, 1–8. Prandtl, L. (1921), ‘Eindringungsfestigkeit und Festigkeit von Schneiden’, Zeitschrift für Angewandte Mathematik und Mechanik 1(4), 15–20. Rahardjo, H. & Fredlund, D. G. (2003), ‘Ko-volume change charactersitics of an unsaturated soil with respect to various loading paths’, Canadian Geotechnical Journal 26(1), 1–11. Rampino, C., Mancuso, C. & Vinale, F. (1999), ‘Laboratory testing on an unsaturated soil: equipment, procedures, and first experimental results’, Canadian Geotechnical Journal 36, 1–12. Rampino, C., Mancuso, C. & Vinale, F. (2000), ‘Experimental behavior ang modelling of an unsaturated compacted soil’, Canadian Geotechnical Journal 37, 748–763. Reeve, M. J., Smith, P. D. & Thomasson, A. J. (1973), ‘The effect of density on water retention properties of field soils’, Journal of Soil Science 24(3), 355–367. Reginato, R. J. & van Bavel, C. H. M. (1962), ‘Pressure cell for soil cores’, Soil Science Society of America Journal 26, 1–3. Rendulic, L. (1936), Relation between void ratio and effective principles stresses for a re- moulded silty clay, in ‘1st Int. Conf. Soil Mech. Found. Eng.’, Cambridge, MA, pp. 48–51.
BIBLIOGRAPHY 261 Reynolds, W. & Elrick, D. (1991), ‘Determination of hydraulic conductivity using a tension infiltrometer’, Soil Science Society of America Journal 55, 633–639. Richards, L. A. (1928), ‘The usefulness of capillary potential to soil moisture and plant in- vestigators’, Journal of Agricultural Research 37, 719–742. Richards, L. A. (1931), ‘Capillary conduction of liquids thgrough porous medium’, Physics 1, 318–333. Richards, L. A. (1941), ‘A pressure-membrane extraction apparatus for soil solution’, Soil Science 51, 377–386. Richards, L. A. (1947), ‘Pressure-membrane apparatus - constrution and use’, Agricultural Engineering 28, 451–454. Richards, L. A. & Weaver, L. R. (1944), ‘Moisture retention by some irrigated soils related to soil moisture tension’, Journal of Agricultural Research 69, 215–235. Richards, S. & Weeks, L. (1953), ‘Capillary conductivity values from moisture yield and tension measurements on soil columns’, Soil Science Society of America Journal 55, 206– 209. Ridley, A. M. & Burland, J. B. (1993), ‘A new instrument for the measurement of soil suction’, Géotechnique 43(2), 321–324. Ridley, A. M. & Wray, W. K. (1996), Suction measurement: A review of current theory and practices, in E. E. Alonso & P. Delage, eds, ‘1st International Conference on Unsaturated Soils (UNSAT 95)’, Balkema, Rotterdam, Paris, pp. 1293–1322. Robinson, D. A., Gardner, C. M. K., Evans, J., Cooper, J. D., Hodnett, M. G. & Bell, J. P. (1998), ‘The dielectric calibration of capacitance probes for soil hydrology using an oscillation frequency response mode’, Hydrology and Earth System Sciences (2), 83–92. Robinson, D. A., Jones, S. B., Wraith, J. M., Or, D. & Freidman, S. P. (2003), ‘A review of advance s in dielctric and electrical conductivity measurements in soils using time domain reflectometry’, Vadose Zone Journal 2, 444–475. Rogers, J. S. & Klute, A. (1971), ‘The hydraulic conductivity-water content relationship during nonsteady flow through a sand column’, Soil Science Society of America Journal 35, 695–700. Rojas, E. & Rojas, F. (2005), ‘Modeling hysteresis of the soil-water characteristic curve’, Japanese Geotechnical Society 45(3), 135–145.
Page 1:
Hydro-Mechanical Properties of Part
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Acknowledgement The present dissert
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3.2 Steps of Model Building . . . .
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11 Summary and Outlook 205 11.1 Gen
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2.16 Influence of Brooks and Corey
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6.2 Experimental results of soil-wa
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7.17 Unsaturated hydraulic conducti
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B.6 Experimental results and best f
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8.3 Constitutive parameters for the
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E ref ur Oedometer reference stiffn
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ρ Density (g/cm 3 ) ρd ρs Dry de
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2 CHAPTER 1. INTRODUCTION Figure 1.
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4 CHAPTER 1. INTRODUCTION - Model b
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6 CHAPTER 1. INTRODUCTION
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8 CHAPTER 2. STATE OF THE ART condu
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10 CHAPTER 2. STATE OF THE ART soil
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12 CHAPTER 2. STATE OF THE ART the
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14 CHAPTER 2. STATE OF THE ART Figu
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16 CHAPTER 2. STATE OF THE ART - Su
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18 CHAPTER 2. STATE OF THE ART - Re
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20 CHAPTER 2. STATE OF THE ART Volu
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22 CHAPTER 2. STATE OF THE ART Drai
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24 CHAPTER 2. STATE OF THE ART wher
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26 CHAPTER 2. STATE OF THE ART drai
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28 CHAPTER 2. STATE OF THE ART Tabl
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30 CHAPTER 2. STATE OF THE ART Tabl
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32 CHAPTER 2. STATE OF THE ART by W
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34 CHAPTER 2. STATE OF THE ART proc
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36 CHAPTER 2. STATE OF THE ART - Im
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38 CHAPTER 2. STATE OF THE ART auth
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40 CHAPTER 2. STATE OF THE ART 2.5.
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46 CHAPTER 2. STATE OF THE ART fitt
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48 CHAPTER 2. STATE OF THE ART Satu
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50 CHAPTER 2. STATE OF THE ART when
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52 CHAPTER 2. STATE OF THE ART Degr
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54 CHAPTER 2. STATE OF THE ART 1. T
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56 CHAPTER 2. STATE OF THE ART 0.2
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58 CHAPTER 2. STATE OF THE ART meth
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60 CHAPTER 2. STATE OF THE ART When
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62 CHAPTER 2. STATE OF THE ART Vert
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64 CHAPTER 2. STATE OF THE ART a) S
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66 CHAPTER 2. STATE OF THE ART - Ja
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68 CHAPTER 2. STATE OF THE ART
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70 CHAPTER 3. INTRODUCTION TO PROCE
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76 CHAPTER 4. EXPERIMENTAL SETUPS s
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78 CHAPTER 4. EXPERIMENTAL SETUPS 1
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80 CHAPTER 4. EXPERIMENTAL SETUPS D
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82 CHAPTER 4. EXPERIMENTAL SETUPS d
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84 CHAPTER 4. EXPERIMENTAL SETUPS b
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86 CHAPTER 4. EXPERIMENTAL SETUPS t
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90 CHAPTER 4. EXPERIMENTAL SETUPS D
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94 CHAPTER 4. EXPERIMENTAL SETUPS T
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96 CHAPTER 5. MATERIAL USED AND EXP
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98 CHAPTER 5. MATERIAL USED AND EXP
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100 CHAPTER 5. MATERIAL USED AND EX
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116 CHAPTER 6. EXPERIMENTAL RESULTS
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136 CHAPTER 7. ANALYSIS AND INTERPR
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138 Observed values (-) Observed va
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164 Stiffness modulus (kPa) Stiffne
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172CHAPTER 8. NEW SWCC MODEL FOR SA
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186 CHAPTER 9. NUMERICAL SIMULATION
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CHAPTER 10. BEARING CAPACITY OF A S
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204 CHAPTER 10. BEARING CAPACITY OF
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206 CHAPTER 11. SUMMARY AND OUTLOOK
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208 CHAPTER 11. SUMMARY AND OUTLOOK
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Page 240 and 241: 214 APPENDIX A. DETAILS ZOU’S MOD
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Page 256 and 257: 230 APPENDIX C. COLLAPSE POTENTIAL
Page 258 and 259: 232 Vertical strain (-) Vertical st
Page 260 and 261: 234 APPENDIX E. NEW SWCC MODEL - DE
Page 266 and 267: 240 40 50 30 APPENDIX E. NEW SWCC M
Page 268 and 269: 242 Observed Values Number of obser
Page 270 and 271: 244 BIBLIOGRAPHY Aubertin, M., Mbon
Page 272 and 273: 246 BIBLIOGRAPHY Campbell, J. D. (1
Page 274 and 275: 248 BIBLIOGRAPHY Davis, J. L. & Ann
Page 276 and 277: 250 BIBLIOGRAPHY Ferré, P. A. & To
Page 278 and 279: 252 BIBLIOGRAPHY Grozic, J. L. H.,
Page 280 and 281: 254 BIBLIOGRAPHY Janbu, N. (1969),
Page 282 and 283: 256 BIBLIOGRAPHY Lawton, E. C., Fra
Page 284 and 285: 258 BIBLIOGRAPHY Mualem, Y. (1977),
Page 288 and 289: 262 BIBLIOGRAPHY Rojas, J. C., Sali
Page 290 and 291: 264 BIBLIOGRAPHY Stoimenova, E., Da
Page 292 and 293: 266 BIBLIOGRAPHY Vanapalli, S. K. &
Page 294 and 295: 268 BIBLIOGRAPHY Unsaturated Geotec
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Page 298: Herausgeber: Th. Triantafyllidis 32
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